EP2058443B1 - Flush toilet - Google Patents
Flush toilet Download PDFInfo
- Publication number
- EP2058443B1 EP2058443B1 EP07806231.2A EP07806231A EP2058443B1 EP 2058443 B1 EP2058443 B1 EP 2058443B1 EP 07806231 A EP07806231 A EP 07806231A EP 2058443 B1 EP2058443 B1 EP 2058443B1
- Authority
- EP
- European Patent Office
- Prior art keywords
- water
- flush
- spouting
- rim
- volume
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims description 974
- 238000011010 flushing procedure Methods 0.000 claims description 38
- 239000002699 waste material Substances 0.000 claims description 26
- 230000009471 action Effects 0.000 claims description 20
- 230000002265 prevention Effects 0.000 description 36
- 230000000694 effects Effects 0.000 description 22
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- 238000003287 bathing Methods 0.000 description 1
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- 238000007664 blowing Methods 0.000 description 1
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Images
Classifications
-
- E—FIXED CONSTRUCTIONS
- E03—WATER SUPPLY; SEWERAGE
- E03D—WATER-CLOSETS OR URINALS WITH FLUSHING DEVICES; FLUSHING VALVES THEREFOR
- E03D5/00—Special constructions of flushing devices, e.g. closed flushing system
- E03D5/01—Special constructions of flushing devices, e.g. closed flushing system using flushing pumps
-
- E—FIXED CONSTRUCTIONS
- E03—WATER SUPPLY; SEWERAGE
- E03D—WATER-CLOSETS OR URINALS WITH FLUSHING DEVICES; FLUSHING VALVES THEREFOR
- E03D11/00—Other component parts of water-closets, e.g. noise-reducing means in the flushing system, flushing pipes mounted in the bowl, seals for the bowl outlet, devices preventing overflow of the bowl contents; devices forming a water seal in the bowl after flushing, devices eliminating obstructions in the bowl outlet or preventing backflow of water and excrements from the waterpipe
- E03D11/02—Water-closet bowls ; Bowls with a double odour seal optionally with provisions for a good siphonic action; siphons as part of the bowl
-
- E—FIXED CONSTRUCTIONS
- E03—WATER SUPPLY; SEWERAGE
- E03D—WATER-CLOSETS OR URINALS WITH FLUSHING DEVICES; FLUSHING VALVES THEREFOR
- E03D3/00—Flushing devices operated by pressure of the water supply system flushing valves not connected to the water-supply main, also if air is blown in the water seal for a quick flushing
-
- E—FIXED CONSTRUCTIONS
- E03—WATER SUPPLY; SEWERAGE
- E03D—WATER-CLOSETS OR URINALS WITH FLUSHING DEVICES; FLUSHING VALVES THEREFOR
- E03D5/00—Special constructions of flushing devices, e.g. closed flushing system
- E03D5/10—Special constructions of flushing devices, e.g. closed flushing system operated electrically, e.g. by a photo-cell; also combined with devices for opening or closing shutters in the bowl outlet and/or with devices for raising/or lowering seat and cover and/or for swiveling the bowl
-
- E—FIXED CONSTRUCTIONS
- E03—WATER SUPPLY; SEWERAGE
- E03D—WATER-CLOSETS OR URINALS WITH FLUSHING DEVICES; FLUSHING VALVES THEREFOR
- E03D2201/00—Details and methods of use for water closets and urinals not otherwise provided for
- E03D2201/30—Water injection in siphon for enhancing flushing
Definitions
- the present invention relates to a flush toilet, and more particularly to a flush toilet flushed with pressurized flush water.
- water main direct-pressure type flush toilets in which flush water is supplied directly from a water main, have become more prevalent.
- the toilet is generally flushed in a sequence whereby water is spouted from a rim spout at the top of the bowl portion, then from a jet spout at the bottom portion of the bowl portion, then a second time from the rim spout, each for a predetermined time.
- water main direct pressure-type flush toilets do not require a tank for holding all of the flush water for a single flush, they have the advantage that they can be made more compact, but on the other hand have the problem that it may be difficult to supply flush water at an adequate flow rate in localities with low water main pressure, making them difficult to install.
- the duration of water spouting from the rim spout or the jet spout when flushing the toilet is generally set to be such that the amount of flush water expelled is sufficient even when a water main direct pressure-type flush toilet is installed in an locality with relatively low water main pressure.
- the problem therefore arises that the amount of flush water expelled is excessive when a water main direct pressure-type flush toilet is installed in a normal water main pressure locality.
- Patent Citation 1 describes a flush water supply device for a toilet.
- a pressure sensor or flow rate sensor is disposed on the water supply path to the rim spout, and a flush water spouting time is set based on values detected by the sensor.
- an appropriate volume of flush water can be supplied by using a long spout time in localities with low water main pressure, and a short spout time in localities with high water main pressure.
- Document JP2005-264469A discloses a flush toilet according to the preamble of independent claim 1 and according to the preamble of independent claim 5.
- water main direct pressure-type flush toilets are generally configured so that flush water is spouted via a constant flow valve, so that flush water flow rate will not be excessive even in localities with high water main pressure.
- flow rates set by the constant flow valve vary greatly from unit to unit, so water spouting times are set such that the volume of flush water spouted is sufficient even when constant flow valves having the lowest flow within this range of variability are used. Therefore the problem arises that flush water volume is excessive when constant flow valves with a large flow rate within the range of variability are used.
- the present invention thus has the object of providing a flush toilet capable of supplying an appropriate volume of flush water while being installable in localities having a low water main pressure.
- the present invention also has the object of providing a flush toilet capable of constantly supplying an appropriate volume of flush water even when there is great variability between the constant flow valves being used.
- the present invention is a flush toilet according to claim 1.
- This flush toilet is flushed by pressurized flush water, comprising a flush toilet main body furnished with a bowl portion on which a rim water spouting port and a jet water spouting port are formed, and a drain trap pipe; a pressurizing pump for pressurizing flush water spouted from the jet water spouting port; a holding tank for holding flush water to be pressurized by the pressurizing pump; flush control means for causing flush water to be spouted from the rim water spouting port for a predetermined rim spouting time using water main supply pressure, and for flushing the bowl portion by causing a predetermined jet spouting volume of flush water in the holding tank to be spouted from the jet spouting port using the pressurizing pump; flush water replenishment means for supplying flush water from the water main to the holding tank after flushing the bowl portion,
- the flush control means expels flush water from the rim water spouting port over a predetermined rim spouting time using water main supply pressure. Also, the flush control means expels only a predetermined jet water spout volume of flush water held in a holding tank from a jet water spout using a pressurizing pump.
- a flush water replenishment means supplies flush water from the water main to the holding tank and restores the held water volume in the holding tank to a pre-flush predetermined holding volume
- a clock means detects the water replenishment time from the start of supply of flush water until the holding tank held water volume is restored to the predetermined held water volume.
- a spout water time adjustment means adjusts the rim spouting time for the next toilet flush based on the water replenishment time detected by the clock means.
- flush water spouted from the jet water spout is pressurized by a pressurizing pump, therefore the toilet can be flushed even in localities where water main supply pressure is low. Because the rim spouting time is adjusted by the water spouting time adjusting means, an appropriate volume of flush water can be supplied.
- the flush control means is preferably constituted to sequentially execute a first water spouting from the rim water spouting port, a water spouting from the jet water spouting port, and a second water spouting from the rim water spouting port, and the water spouting time adjustment means adjusts the duration of the second rim water spouting from the rim water spouting port.
- the water spouting time adjustment means adjusts the second rim spouting time from the rim water spout, therefore problems such as breakage of the water seal in the drain trap caused by insufficient water spouting, or overflowing of large volumes of flush water from the bowl portion due to excess rim water spouting can be prevented.
- the flush water replenishment means commences supplying water to the holding tank after waiting a predetermined water supply wait time.
- a float switch for detecting the water level in the holding tank, and the clock means detects the time up until a predetermined water volume is detected by the float switch.
- the present invention is furthermore a flush toilet according to independent claim 5.
- This flush toilet is flushed by pressurized flush water, comprising a flush toilet main body furnished with a bowl portion on which a rim water spouting port and a jet water spouting port are formed, and a drain trap pipe; a pressurizing pump for pressurizing flush water spouted from the jet water spouting port; a holding tank for holding flush water to be pressurized by the pressurizing pump; flush control means for causing flush water to be spouted from the rim water spouting port using water main supply pressure, and for causing flush water in the holding tank to be spouted from the jet spouting port using the pressurizing pump; flush water replenishment means for supplying flush water from a water main to the holding tank after jet water spouting is completed, thereby restoring the volume of water held in the holding tank to a predetermined held water volume which is a predetermined pre-flush held water volume
- the rim spouting time or the jet water spouting volume are adjusted, therefore even if there are individual differences in the constant flow valves used or the like, water waste can be prevented as toilet flushing capability is maintained.
- the water spouting volume adjustment means adjusts the jet water spouting volume by changing the duration of the pressurizing pump operation.
- appropriate toilet flushing parameters can be set by changing the jet spouting time to change the jet water spouting volume.
- the water spouting volume adjustment means adjusts the jet water spouting volume by varying the rpm of the pressurizing pump.
- the jet spout water volume is varied by varying the flow rate of the jet spout water to set appropriate flushing of the toilet.
- jet water spouting comprises a siphon start-up zone in which siphon action is started up, a siphon continuation zone wherein flow rate is less than in the siphon start-up zone, and started-up siphon action is continued, and a blow zone for pushing out waste within the drain trap pipe after completion of the siphon action, and the flush control means operates the pressurizing pump at an rpm approximately equal to that of the siphon start-up zone.
- the siphon action started up in the siphon start-up region is continued in the siphon continuation region as flush water is saved, and floating waste and the like are reliably discharged in the blowing zone.
- the water spouting volume adjustment means preferably adjusts the jet water spouting volume by varying the blow zone time.
- waste can be reliably pushed out from the drain trap pipe even in the flush mode, when generation of a strong siphon action cannot be expected.
- the flush control means performs rim water spouting over a rim spouting time adjusted based on the water replenishment time detected during the previous toilet flush; in cases where the water replenishment time detected in the most recent toilet flush is longer by a predetermined time than the previous water replenishment time, the water level inside the bowl portion will be raised by additional water spouting after the holding tank is restored to the predetermined held water volume.
- the flush control means raises the water level in the bowl portion by additional water spouting, therefore breaking of the drain trap pipe seal can be prevented even when the rim water spouting flow rate in the most recent toilet flushing is greatly reduced compared to the rim spout water flow rate in the previous toilet flush.
- the volume of flush water supplied to the bowl portion by the addition of flush water is determined by the flush control means based on the rim water spouting flow rate and the most recent rim spouting time corresponding to the most recent water replenishment time, so as to seal the drain trap pipe.
- the additional spout water volume is determined based on the rim water spouting flow rate and the rim spouting time, therefore the drain trap pipe can be reliably water sealed, and the occurrence of water waste due to excessive additional water spouting can be prevented.
- the flush toilet of the present invention is capable of supplying an appropriate volume of flush water, and can be installed even in localities with low water main pressure.
- the flush toilet of the present invention can supply a constant appropriate volume of flush water even when there is a large variability between individual constant flow valves used.
- Fig. 1 is a right side elevation of a flush toilet according to the present embodiment.
- Fig. 2 is a top plan view of a flush toilet according to the present embodiment, and Fig. 3 is a left side elevation thereof.
- Fig. 4 is a perspective view looking down diagonally from the rear right of a flush toilet according the present embodiment;
- Fig. 5 is a perspective view looking down diagonally from the rear left thereof.
- Fig. 6 is a cross section along line VI-VI in Fig. 2 .
- Fig. 7 is a block diagram showing the water supply system for the rim water spouting and the jet water spouting. Note that Figs. 2 through 6 show a flush toilet according to the present embodiment in which the toilet seat, the cover, the bidet ("Washlet”), and side panels are removed.
- a flush toilet 1 As shown in Fig. 1 , a flush toilet 1 according to the first embodiment of the present invention has a flush toilet main body 2, a toilet seat 4 disposed on the top surface of the flush toilet main body 2, a cover 6 disposed to cover the toilet seat 4, and a bidet 8 disposed on the rear upper portion of the flush toilet main body 2.
- a functional portion 10 is disposed at the back of the flush toilet main body 2; this functional portion 10 is covered by side panels 10a.
- the flush toilet main body 2 is ceramic; on it are formed a bowl portion 12 for receiving waste, a drain trap pipe 14 extending from the bottom portion of the bowl portion 12, a jet water spouting port 16 for jet-spout water, and a rim water spouting port 18 for rim water spouting.
- the drain trap pipe 14 extends rearward and diagonally upward from the bowl portion 12, then extends downward and connects to a drain pipe D.
- the jet water spouting port 16 is formed at the bottom of the bowl portion 12, and is configured to expel flush water toward the intake to the drain trap pipe 14.
- the rim water spouting port 18 is formed on the left side upper rear of the bowl portion 12, and is configured to expel flush water along the edge of the bowl portion 12.
- the flush toilet 1 according to the first embodiment of the present invention is directly connected to a water main supplying flush water; flush water is expelled from the rim water spouting port 18 by the water main supply pressure.
- the toilet With respect to jet spout water, the toilet is configured so that flush water held in the holding tank contained in the functional portion 10 is pressurized by the pressurizing pump and expelled in a high flow rate from the jet water spouting port 16.
- a rim spout water supply system built into the functional portion 10 as a rim spout water supply system are a constant flow valve 20, a rim spout water electromagnetic valve 22, a rim spout water vacuum breaker 24, and a rim spout water flapper valve 26.
- a tank water supply electromagnetic valve 28 built into the functional portion 10 as a jet spout water supply system are a tank water supply electromagnetic valve 28, a tank water supply vacuum breaker 30, a holding tank 32, a pressurizing pump 34, a jet water spouting vacuum breaker 36, and a jet water spouting flapper valve 38.
- the rim spout water electromagnetic valve 22 the tank water supply electromagnetic valve 28, and a controller 40 ( Fig. 7 ) serving as a flush control means for controlling the pressurizing pump 34.
- the constant flow valve 20 is configured so that flush water flowing in from a water intake 20a through a stop cock 42a, a splitter hardware 42b, and a strainer 42c (shown in Fig. 7 ) is constrained down to a predetermined flow rate.
- the constant flow valve 20 is configured so that the flow rate of flush water is limited to 16 liters/minute or less.
- Flush water passing through the constant flow valve 20 is split into two streams, connected so that one flows to the rim spout water electromagnetic valve 22, and the other to the tank water supply electromagnetic valve 28.
- the constant flow valve 20 is disposed on the rear left side of the flush toilet main body 2.
- the rim spout water electromagnetic valve 22 is opened and closed by a control signal from a controller 40, thereby expelling or stopping flush water from the rim water spouting port 18.
- the rim spout water electromagnetic valve 22, as with the constant flow valve 20, is disposed to the rear and left of the flush toilet main body 2.
- the rim spout water vacuum breaker 24 is disposed midway on the opening 18a which guides flush water that has passed through the rim spout water electromagnetic valve 22 to the rim water spouting port 18, and prevents the backward flow of flush water from the rim water spouting port 18.
- the rim spout water vacuum breaker 24 is disposed approximately 25.4 mm (approximately 1 inch) above the top edge surface of the bowl portion 12, and reliably prevents backflow. Note that in the present embodiment the rim spout water vacuum breaker 24 is disposed at the top of the drain trap pipe 14, at the center rear of the flush toilet main body 2.
- the rim spout water flapper valve 26 is disposed on the opening 18a on the downstream side of the rim spout water vacuum breaker 24, and prevents backflow from the rim water spouting port 18.
- the series arrangement of the rim spout water vacuum breaker 24 and the rim spout water flapper valve 26 on the rim water spouting port 18 more reliably prevents backflow of the flush water.
- the rim spout water flapper valve 26 is disposed at the top of the jet water spouting flapper valve 38 on the rear left side of the flush toilet main body 2.
- the tank water supply electromagnetic valve 28 is opened and closed by a controller 40, and supplies or stops the supply of flush water to the holding tank 32.
- the tank water supply electromagnetic valve 28 is disposed similarly to the constant flow valve 20, at the rear left side of the flush toilet main body 2.
- the tank water supply vacuum breaker 30 is disposed midway on the tank water supply path 32a guiding flush water which has passed through the tank water supply electromagnetic valve 28 to the holding tank 32, and prevents backflow of flush water from the holding tank 32.
- the tank water supply vacuum breaker 30 is disposed approximately 25.4 mm (approximately 1 inch) above the top edge surface of the bowl portion 12, and reliably prevents backflow. Note that in the present embodiment, the tank water supply vacuum breaker 30 is disposed above the drain trap pipe 14 at the center of the flush toilet main body 2.
- the holding tank 32 is configured to be able to hold flush water to be spouted from the jet water spouting port 16. Note that in the present embodiment the holding tank 32 is disposed so as to extend from the rear right side of the flush toilet main body 2 up to the top of the drain trap pipe 14 at the rear center of the flush toilet main body 2, and has an interior volume of approximately 3 liters.
- a resin attaching frame 2a serving as an attaching portion is affixed at the rear of the flush toilet main body 2; this flush toilet main body 2 is constituted as a separate entity from the flush toilet main body 2, and is formed in approximately a rectangular shape so as to surround the perimeter of the holding tank 32.
- the holding tank 32 is suspended from the attaching frame 2a such that the flange portion at the upper edge thereof engages the attaching frame 2a.
- the end of the holding tank 32 is opened in the vicinity of the bottom portion of the holding tank 32; noise during the supply of water is reduced by supplying water to the holding tank 32 in a state whereby the end of the tank water supply path 32a is immersed in water.
- a float switch 32b is disposed on the inside of the holding tank 32, and is configured to detect the water level inside the holding tank 32. The float switch 32b switches to ON when the water level inside the holding tank 32 reaches a predetermined holding water level; the controller 40 detects this and causes the tank water supply electromagnetic valve 28 to close.
- the pressurizing pump 34 is configured to pressurize the flush water held in the holding tank 32, causing it to be expelled from the jet water spouting port 16.
- the pressurizing pump 34 is disposed below the holding tank 32, i.e. at the rear right side of the flush toilet main body 2, and on the side of the drain trap pipe 14.
- two downward-extending U-shaped metal plates 32c extending rearward are attached to the bottom surface of holding tank 32, and the pressurizing pump 34 is suspended below the holding tank 32 using these metal plates 32c.
- an impeller 34a for pressurizing flush water
- a motor 34b for driving the impeller 34a
- a water removal plug 34c is connected to the pressurizing pump 34, and leaving this water removal plug 34c open enables flush water in the holding tank 32 or the pressurizing pump 34 to be drained for maintenance or the like.
- a water receiving tray 2b is also disposed under the pressurizing pump 34 to receive condensed water droplets or leaked water.
- the holding tank 32 is connected to the pressurizing pump 34 through an U-shaped pipe 34d which extends from the holding tank 32 toward the front of the flush toilet main body 2 and then U-turned to the rear.
- flush water pressurized by the pressurizing pump 34 flows into the jet water spouting vacuum breaker 36 via a crossing pipe 34e extending across the flush toilet main body 2 at the rear side of the drain trap pipe 14.
- the pressurizing pump 34 pressurizes flush water in the holding tank 32 and expels flush water from the jet water spouting port 16 at a maximum flow rate of approximately 100 liters/minute.
- the jet water spouting vacuum breaker 36 is connected on the downstream side to the pressurizing pump 34, and prevents backflow into the holding tank 32 side of water accumulated in the bowl portion 12, while forming a partition between those parts. This makes it possible to set the held water level in the holding tank 32 to be higher than the accumulated water level inside the bowl portion 12.
- the jet water spouting vacuum breaker 36 is disposed on the left side of the drain trap pipe 14 at the rear of the flush toilet main body 2.
- the jet water spouting flapper valve 38 is connected on the downstream side to the jet water spouting vacuum breaker 36, and prevents backflow of flush water from the jet water spouting port 16.
- the serial placement of the jet water spouting vacuum breaker 36 and the jet water spouting flapper valve 38 enables more reliable prevention of backflow of the flush water.
- Flush water which has passed through the jet water spouting flapper valve 38 is expelled from the jet water spouting port 16 via a jet-side water supply path 16a.
- the jet water spouting flapper valve 38 is disposed on the left side of the drain trap pipe 14 at the rear of the flush toilet main body 2.
- flush water held in the holding tank 32 disposed on the right side of the drain trap pipe 14 and pressurized by the pressurizing pump 34 passes through the crossing pipe 34e and reaches the left side located on the opposite side relative to the drain trap pipe 14, passing through the jet water spouting vacuum breaker 36, the jet water spouting flapper valve 38, and the jet-side water supply path 16a disposed there, to be expelled from the jet water spouting port 16.
- the jet water spouting flapper valve 38 is disposed under the rim spout water flapper valve 26 at the rear left side of the flush toilet main body 2. Therefore the rim side water supply path 18a extending from the rim spout water flapper valve 26 up to the rim water spouting port 18 is also disposed on the same side as the jet-side water supply path 16a relative to the drain trap pipe 14.
- the controller 40 serving as a flush control means sequentially operates the rim spout water electromagnetic valve 22 and the pressurizing pump 34 under user manipulation of a toilet flushing switch (not shown), causing spouting of water to commence in sequence from the rim water spouting port 18 and the jet water spouting port 16 so as to flush the bowl portion 12.
- the controller 40 opens up the tank water supply electromagnetic valve 28 to replenish flush water to the holding tank 32, and when the float switch 32b detects the predetermined holding amount, the tank water supply electromagnetic valve 28 is closed and supply of water is stopped. Therefore the tank water supply electromagnetic valve 28 operates as a flush water replenishment means.
- a clock means 40a for measuring the time after commencement of replenishment of flush water to the holding tank 32 until it is detected by the float switch 32b to be at the predetermined holding water level.
- the controller 40 also has built into it a water spouting time adjustment means 40b for adjusting the time during which flush water is spouted from the rim water spouting port 18 based on the time measured by the clock means 40a.
- the controller 40 has a temperature sensor 40c, which is a temperature detecting means for measuring the temperature in the room where the flush toilet 1 is installed, a freeze prevention control means 40d for implementing a freeze prevention operation if there is a risk that flush water in the flush toilet 1 will freeze, and a timer 40e for counting time intervals for freeze prevention operation.
- the controller 40 comprises a CPU, a memory, and a program to operate those.
- Fig. 8 is a cross section of the jet water spouting vacuum breaker 36.
- the jet water spouting vacuum breaker 36 has a valve main body 44 on which are formed a water intake 44a and a water outlet 44b, a vacuum breaker top 46 disposed within this valve main body 44 so as to be vertically movable, and a vacuum breaker main body 48 attached to the valve main body 44, on which is formed an atmosphere opening port 48a.
- valve main body 44 water intake 44a is open toward the vertical direction, and is connected to communicate with the crossing pipe 34e.
- the water outlet 44b is open toward the horizontal direction, and is connected to the intake of the jet water spouting flapper valve 38.
- the vacuum breaker top 46 has an approximately disk-shaped vacuum body portion 46a, and a shaft portion 46b extending vertically from the center of this vacuum body portion 46a.
- a bottom surface seal material 46 for closing the water intake 44a is further attached to the bottom surface of the vacuum body portion 46a, and a top surface seal material 46 for closing the atmosphere opening port 48a is attached to the top surface of the vacuum body portion 46a.
- the vacuum breaker main body 48 is an approximately disk-shaped member; the atmosphere opening port 48a is formed on the bottom end thereof, and the lower portion thereof is inserted into the valve main body 44.
- a guide portion 48b for slidably accepting the vacuum breaker top 46 shaft portion 46b is provided on the top of the center axis line of the vacuum breaker main body 48. Acceptance of the shaft portion 46b into the guide portion 48b results in the vacuum breaker top 46 being slidably supported between a lower position at which the bottom surface seal material 46 closes the water intake 44a, and an upper position at which the top surface seal material 46 closes the atmosphere opening port 48a.
- the water outlet 44b communicates with the atmosphere opening port 48a, the water intake 44a and the water outlet 44b are separated, and the holding tank 32 in communication with the water intake 44a ceases to move in tandem with the water level of the bowl portion 12 in communication with the water outlet 44b.
- FIGs. 9 through 13 are perspective views and side elevations showing a procedure for removing the holding tank 32 and the pressurizing pump 34 as a single unit from the flush toilet main body 2 in the upward direction.
- U-pipe 34d connecting portions 50a and 50b connecting the holding tank 32 and the pressurizing pump 34 are removed by inserting one's hand from the side surface of the functional portion 10, which has been exposed by first removing the side panels 10a.
- a connecting portion 50c connecting the pressurizing pump 34 and the crossing pipe 34e is removed, as are electrical connectors (not shown) connected to the pressurizing pump 34.
- the holding tank 32 which is suspended from the attaching frame 2a, is removed by pulling it upward from the flush toilet main body 2.
- the pressurizing pump 34 which is suspended from the holding tank 32 by the metal plates 32c, is removed as an integral piece.
- Fig. 14 is a graph showing the timing at which the pressurizing pump 34 operates.
- Fig. 15 is a flow chart showing the flushing operations in the flush toilet 1.
- Step S0 in Fig. 15 operation of a toilet flush switch (not shown) causes an advance to Step S 1, and the first rim water spouting is commenced. That is, when a user operates the toilet flushing switch (not shown) at time t0 in Fig. 14 , the controller 40 sends a signal to the rim spout water electromagnetic valve 22 to open, and flush water is expelled from the rim water spouting port 18 by water main pressure. When the rim spout water electromagnetic valve 22 is opened, flush water supplied from the water main flows into the constant flow valve 20 via the stop cock 42a, the splitter hardware 42b, and the strainer 42c.
- Step S2 the system advances to Step S2, and jet water spouting is commenced. That is, at time t1 in Fig. 14 the controller 40 sends a signal to the pressurizing pump 34 to turn ON. When the pressurizing pump 34 is turned ON, the flush water held in the holding tank 32 is pressurized. After flush water pressurized by the pressurizing pump 34 disposed on the rear right side of the flush toilet main body 2 flows through the crossing pipe 34e to the opposite side of the drain trap pipe 14, it reaches the jet water spouting vacuum breaker 36 disposed on the right side of the drain trap pipe 14.
- the controller 40 sends a signal to the rim spout water electromagnetic valve 22 to close, and water spouting from the rim water spouting port 18 is stopped. That is, in times t1-t2, water spouting from the jet water spouting port 16 and water spouting from the rim water spouting port 18 are carried out simultaneously.
- the start-up sound of the pressurizing pump 34 is masked by the sound of rim water spouting, and does not stand out.
- the controller 40 sends a signal to the pressurizing pump 34 causing the rpm of the motor 34 built into the pressurizing pump 34 to the gradually decrease.
- the water spouting flow rate from the jet water spouting port 16 also gradually decreases in essentially a linear manner with respect to time.
- Step S3 in Fig. 15 whereby the second rim spouting is commenced. That is, at time t5 in Fig. 14 the controller 40 sends a signal to the rim spout water electromagnetic valve 22 to open, and the second spouting from the rim water spouting port 18 is commenced. This causes the water spouted from the rim water spouting port 18 to overlap the water spouted from the jet water spouting port 16, which is gradually diminishing in spout flow rate.
- the flow rate of flush water discharged from the drain trap pipe 14 is essentially equal to the flow rate of flush water flowing in from the jet water spouting port 16, so the siphon effect in the drain trap pipe 14 is continued without interruption.
- gradually decreasing the volume of water spouted from the jet water spouting port 16 down from the maximum flow rate prevents the occurrence of a large siphon cutoff sound caused by a sudden halting of the siphon effect.
- the reduction in spouted water flow rate is further ameliorated, and the sound occurring when the siphon effect stops is further reduced.
- the rpm of the gradually reduced motor 34 reaches zero at time t6 in Fig. 14 , and the pressurizing pump 34 stops. Operation of the pressurizing pump 34 between times t1-t6 causes a predetermined volume of jet spouted water to be expelled from the jet water spouting port 16, and the volume of water held in the holding tank 32 becomes approximately zero. Spouting of water from the jet water spouting port 16 is stopped as a result of the pressurizing pump 34 being stopped. This causes the jet water spouting vacuum breaker 36 vacuum breaker top 46 ( Fig. 8 ) to close the water intake 44a, so that accumulated water in the bowl portion 12 is separated from the flush water in the holding tank 32.
- the controller 40 controls the pressurizing pump 34 to cause water to be spouted for approximately 2 seconds at the maximum flow rate from the jet water spouting port 16, then to gradually reduce the spout water flow rate so that the spout water flow rate goes to zero in approximately 1 second. Control is preferably effected so that after spouting at the maximum flow rate for 1.5 to 2.0 seconds, the spout water flow rate goes to zero in 1.5 to 2.0 seconds.
- Step S4 replenishment of flush water to the holding tank 32 is commenced, and the clock means 40a built into the controller 40 begins counting water replenishment time until the holding tank 32 returns to a predetermined holding volume. That is, after spouting of water from the rim water spouting port 18 is stopped, and a predetermined water supply wait time has elapsed, the controller 40 sends a signal at a time t8 to the tank water supply electromagnetic valve 28 to open. This is to avoid the effects of rim water spouting on the water supply pressure to the holding tank 32.
- the pressure of water supplied to the holding tank 32 drops in the state in which the rim spout water electromagnetic valve 22 is completely closed.
- Supply of water to the holding tank 32 is therefore commenced after a predetermined water supply wait time has elapsed and the rim spout water electromagnetic valve 22 has completely closed.
- a predetermined water supply wait time In the present embodiment 0.5 seconds is used as the water supply wait time t8-t7. This water supply wait time could be eliminated, but if used a setting of 1 second or less is preferred.
- flush water which has flowed in from the water intake 20a passes through the tank water supply electromagnetic valve 28 disposed on the rear left side of the flush toilet main body 2 and through the tank water supply path 32a, then flows into the tank water supply vacuum breaker 30 above the drain trap pipe 14 at the rear center of the flush toilet main body 2.
- Flush water which has passed through the tank water supply vacuum breaker 30 flows on the right side of the drain trap pipe 14, then flows into the holding tank 32 from the end of the tank water supply path 32a extending up to the vicinity of the bottom portion of the holding tank 32.
- the end of the tank water supply path 32a in which the flush water flows is in an essentially submerged state within the holding tank 32, thus reducing the noise occurring when flush water flows into the holding tank 32.
- Step S6 in Fig.15 a determination is made as to whether the float switch 30, which had been in the OFF state, is now ON; if it is in the OFF state, the Step S6 process is repeated.
- the float switch 32b goes ON (time t9 in Fig. 14 ).
- the system advances to Step S7, and the tank water supply electromagnetic valve 28 is closed.
- the controller 40 sends a signal to the tank water supply electromagnetic valve 28 to close.
- the clock means 40a ends the measurement of water replenishment time.
- the second rim spouting time for the next toilet flush (t5-t7 in Fig. 14 ) is determined by the water spouting time adjustment means 40b built into the controller 40.
- the water spouting time adjustment means 40b calculates a moving average value for the past 50 water replenishment times calculated by the clock means 40a. In other words, it calculates an average value Tav for the most recent 50 iterations of the water replenishment time Te-Ts, which is the elapsed time from time Ts (t8 in Fig 14 ) when the tank water supply electromagnetic valve 28 was released up until the time it was closed Te (t9 in Fig. 14 ).
- the water spouting time adjustment means 40b judges that the flush toilet 1 is installed in a locality where the supply water pressure is the normal 0.07 MPa.
- the water spouting time adjustment means 40b judges that the flush toilet 1 is installed in a locality with low supply water pressure.
- the water spouting time adjustment means 40b judges that the flush toilet 1 is installed in a locality with extremely low supply water pressure of less than 0.03 Mpa.
- the water spouting time adjustment means 40b sets the second rim spouting time to be short in the next toilet flushing, and when the supply water pressure is low, it sets the second rim spouting time to be long.
- the water spouting time adjustment means 40b judges that the flush toilet 1 is installed in a normal locality, it sets the second rim spouting time for the next toilet flushing to be 3 seconds.
- the water spouting time adjustment means 40b judges that the toilet is in a low-pressure locality, it sets the second rim spouting time to 4 seconds, and when it judges that it is an extremely low pressure locality, it sets that time to 5.5 seconds.
- the water spouting time adjustment means 40b sets the second rim spouting time for the next toilet flushing based on the average time Tav of the most recent 50 water replenishments, but when the number of past toilet flushes is less than 50 it calculates an average value Tav by averaging all past water replenishment times.
- the second rim spouting time is set at 2.5 seconds so that there will not be an insufficiency of flush water.
- Step S9 once the second rim spouting time is determined at the time of the next toilet flushing, the system returns to the Step S0 standby state.
- Fig 16 is a flowchart showing the freeze prevention operation in the flush toilet 1.
- Step S101 is executed following Step S100, which is a standby state in which no toilet flushing is carried out.
- Step S101 a judgment is made as to whether the temperature inside the toilet room measured by the controller 40 temperature sensor 40c is below a predetermined freeze prevention operating temperature.
- the freeze prevention operation after Step S102 is not executed, the system returns to Step S100 and repeats the Step S101 process.
- the freeze prevention operating temperature in the present embodiment is set at 5°C.
- the freeze prevention operation is also executed when a user sets the system to perform the freeze prevention operation using an operating switch (not shown) provided on the flush toilet 1.
- the freeze prevention operation is set by a special operation of an operating switch (not shown).
- the freeze prevention operation is set by operating multiple switches (not shown) originally intended for executing other functions, or by holding down a switch for a predetermined period of time.
- Step S102 when the temperature in the toilet room falls below the freeze prevention operating temperature, the freeze prevention control means 40d releases the rim spout water electromagnetic valve 22 in Step S102.
- Release of the rim spout water electromagnetic valve 22 causes a supply of flush water from the water main to pass through the stopcock 42a, the splitter hardware 42b, the strainer 42c, the constant flow valve 20, the rim spout water electromagnetic valve 22, the rim spout water vacuum breaker 24, the rim spout water flapper valve 26, and the rim side water supply path 18a due to the supply pressure of the water main, so that water is spouted into the bowl portion 12 from the rim water spouting port 18 at a flow rate of approximately 15 liters/minute. Flush water which had accumulated in the water supply system is thus moved, and freezing there is prevented.
- Step S103 is executed, and the freeze prevention control means 40d closes the rim spout water electromagnetic valve 22.
- Step S104 the freeze prevention control means 40d causes the pressurizing pump 34 to turn at a slow speed.
- the pressurizing pump 34 flush water in the holding tank 32 is spouted from the jet water spouting 16 via the pressurizing pump 34, the jet water spouting vacuum breaker 36, the jet water spouting flapper valve 38, and the jet-side water supply path 16a.
- Flush water which had accumulated in the water supply system is thus moved, and freezing there is prevented.
- Step S105 is executed and the freeze prevention control means 40d stops the pressurizing pump 34.
- the pressurizing pump 34 is operated at an rpm such that flush water is spouted from the jet water spouting port 16 at a flow rate of approximately 0.7 liters per minute.
- the above flush water which had accumulated in the water supply system can be moved without generating a siphon effect in the drain trap pipe 14.
- noise generated by the siphon effect can be prevented and waste of flush water can be minimized.
- Step S106 a judgment is made of the state of the float switch 32b.
- the volume of water held in the holding tank 32 is reduced by operating the pressurizing pump 34 for approximately 20 seconds.
- the float switch 32b provided inside the holding tank 32 goes to OFF when the held water volume is below a predetermined replenishment holding volume.
- the freeze prevention control means 40d releases the tank water supply electromagnetic valve 28 and replenishes flush water into the holding tank 32. That is, the holding tank 32 and the tank water supply electromagnetic valve 28 function as a held water maintenance means.
- Step S106 When the held water amount in the holding tank 32 increases to a predetermined held water volume and rises to a predetermined water level, the fact that the float switch 32b has turned ON is detected in Step S106. When it is judged that the float switch 32b has turned ON, the system proceeds to Step S108, wherein the freeze prevention control means 40d closes the tank water supply electromagnetic valve 28. Next, in Step S109, the timer 40e built into the controller 40 commences counting down the time until the freeze prevention operation is next executed. In Step S110, after the timer 40e commences counting, a judgment is made as to whether the predetermined time interval for freeze prevention operation has elapsed. In the present embodiment the time interval for the freeze prevention operation is set at 10 minutes.
- Step S110 If the 10 minute freeze prevention operation interval has not elapsed, processing in Step S110 is repeatedly executed; after 10 minutes have elapsed the system returns to the Step S100 standby state. When the system returns to the Step S100 standby state, it then advances to Step S101, and a judgment is made as to whether the temperature measured by the temperature sensor 40c has risen to a temperature higher than the freeze prevention temperature. If the temperature in the toilet room continues to be lower than the freeze prevention operation temperature, the system advances to Step S102, and the above described process is repeated. On the other hand if the temperature of the toilet room has risen to be higher than the freeze prevention operation temperature, the system returns to Step S100, and the judgment made in Step S101 is repeated.
- Step S102 The freeze prevention operation is also executed after Step S102, when a manual setting is made to implement the freeze prevention operation in the flush toilet 1. This freeze prevention operation is repeated until the freeze prevention operation setting is released by user operation of a control switch (not shown).
- a control switch not shown.
- water spouting from the jet water spouting port 16 and the rim water spouting port 18 will be executed intermittently at approximately 10 minute intervals. By this means flush water accumulated in each of the parts of the flush water toilet 1 is prevented from freezing.
- flush water expelled from a jet water spouting port is pressurized by a pressurizing pump, therefore sufficient toilet flushing can be accomplished even in localities where water main supply pressure is low. Also, because rim spouting time is adjusted by a water spouting time adjustment means, flush water can be supplied in an appropriate volume. Moreover, in the flush toilet of the present embodiment the water main supply pressure is estimated based on the water replenishment time, therefore a separate sensor for measuring pressure is not required.
- a water spouting time adjustment means adjusts the second rim spouting time, therefore breakage of the water seal in the drain trap pipe caused by insufficient rim water spouting and overflow from the bowl portion of large volumes of flush water due to excessive rim water spouting can be prevented.
- the fact that the flush water in the holding tank has reached a predetermined held water volume is detected by a float switch, therefore the time required until the held water in the holding tank is restored to the predetermined held water volume can be accurately detected.
- the water spouting time adjustment means adjusted the second rim spouting time based on a detected water replenishment time, but as a variant the first rim spouting time, or the first and the second rim spouting time, could also be adjusted.
- the replenishment time was divided into three stages, and the rim spouting time was set for each of those divisions, but the method of setting the rim spouting time could be changed as appropriate.
- the rim spouting time could be set to be proportional to the water replenishment time.
- the flush toilet of this embodiment differs from the above-described first embodiment with respect to points such as that the pressurizing pump operating time is adjusted in accordance with the flow rate of flush water supplied through a constant flow valve, that switching between rim water spouting and jet water spouting is accomplished using a switching valve, and that rim water spouting continues even during jet water spouting. Therefore here we shall discuss only those points about the present embodiment which differ from the first embodiment, and we will omit a discussion of points in common.
- Fig. 17 is a block diagram showing the water supply system for rim water spouting and jet water spouting.
- Fig. 18 is a graph showing the timing at which each section operates when the flush toilet is flushed.
- a flush toilet 100 has a flush toilet main body 102 and a functional portion disposed at the rear of the flush toilet main body 102.
- a bowl portion 112 a drain trap pipe 114, a jet spouting port 116, and a rim water spouting port 118 are formed on the flush toilet main body 102.
- the flush toilet 100 according to the second embodiment of the present invention is directly connected to the water main supplying flush water, and flush water is expelled from a rim water spouting port 118 by water main supply pressure.
- flush water held in a holding tank built into the functional portion 110 is pressurized by a pressurizing pump and expelled from a jet water spouting port 116 in a large flow rate.
- a constant flow valve 120, a rim spout water electromagnetic valve 122, a tank water supply electromagnetic valve 128, a rim spout water vacuum breaker 124, and a rim spout water flapper valve 126 are built into the functional portion 110 as a water supply system for rim water spouting.
- a holding tank 132, a pressurizing pump 134, a jet water spouting vacuum breaker 136, and a jet water spouting flapper valve 138 are built into the pressurizing pump 134 as a water supply system for jet water spouting.
- a rim spout water electromagnetic valve 122, a tank water supply electromagnetic valve 128, and a controller 140 serving as a flush control means for controlling the pressurizing pump 134 are built into the functional portion 110.
- a constant flow valve 120 is configured so that flush water flowing in via a stopcock 142a, splitter hardware 142b, and a strainer 142, is constrained so that it is less than a predetermined flow rate.
- the constant flow valve 120 limits the flush water flow rate to a nominal value of 12 liters/minute, but in actuality this flow rate varies between approximately 10-15 liters per minute due to individual differences between constant flow valves 120.
- Flush water passed through the constant flow valve 120 is connected to flow into a switching valve 128 via a electromagnetic valve 122.
- the electromagnetic valve 122 opens and closes according to a control signal from the controller 140, causing flush water into the switching valve 128 to flow or be stopped.
- the switching valve 128 is disposed to divide up the flush water which has passed through the electromagnetic valve 122 into a holding tank 132 side and a rim water spouting port 118 side based on a control signal from the controller 140.
- This switching valve 128 is configured to split up flush water in any desired proportion between the holding tank 132 and the rim water spouting port 118 according to the setting.
- the rim spout water vacuum breaker 124 is disposed at the center of the rim side water supply path 118a which leads flush water passing through the switching valve 128 to the rim water spouting port 118, and prevents backflow of flush water from the rim water spouting port 118.
- the holding tank 132 is configured to the hold flush water which is to be spouted from the jet water spouting port 116.
- the end of the tank supply path 132 connected to the switching valve 128 is disposed to form an air gap relative to the holding tank 132, and prevents the backflow of flush water into the holding tank 132.
- An upper end float switch 132b and a lower end float switch 132c are disposed inside the holding tank 132 for detecting the water level inside the holding tank 132.
- the upper end float switch 132 turns ON when the water level in the holding tank 132 reaches a predetermined held water level; the controller 140 detects this and causes the electromagnetic valve 122 to close.
- the predetermined held water level for the holding tank 132 corresponds to the predetermined held water volume and measured held water volume.
- the lower end float switch 132c is disposed in the vicinity of the bottom surface of the holding tank 132, and turns ON when the water level in the holding tank 132 drops below that lower end float switch 132c; it is configured to detect that the holding tank 132 has become empty.
- the pressurizing pump 134 is constituted to pressurize flush water held in the holding tank 132 and cause it to be expelled from the jet water spouting port 116.
- the jet water spouting vacuum breaker 136 is connected to the downstream side of the pressurizing pump 134, and prevents backflow of water accumulated in the bowl portion 112 into the holding tank 132 side, as well as forming a partition between those elements. Flush water which has passed through the jet water spouting vacuum breaker 136 is expelled from the jet water spouting port 116 via the jet-side water supply path 116a.
- the jet water spouting flapper valve 138 is connected between the holding tank 132 and the pressurizing pump 134; when the water level in the holding tank 132 falls, the flush water in the pressurizing pump 132 flows back to the holding tank 132, and the flush water inside the pressurizing pump 134 is prevented from coming out.
- the controller 140 serving as the flush control means is configured so that the electromagnetic valve 122, the switching valve 128, and the pressurizing pump 134 are operated in sequence by user operation of a toilet flushing switch (not shown) to commence the spouting of water from the rim water spouting port 118 and the jet water spouting port 116 in sequence, thereby flushing the bowl portion 112.
- a toilet flushing switch (not shown) to commence the spouting of water from the rim water spouting port 118 and the jet water spouting port 116 in sequence, thereby flushing the bowl portion 112.
- the electromagnetic valve 122 and the switching valve 128 operate as a flush water replenishment means.
- the controller 140 has built into it a clock means 140a for measuring the time after replenishment of flush water to the holding tank 132 commences until a predetermined holding water level is detected. Furthermore, built into the controller 140 is a water spouting volume adjustment means 140b for adjusting the rim spouting time, i.e. the volume of flush water spouted, from the rim water spouting port 118, or for adjusting the volume of flush water spouted from the jet water spouting port 116. Specifically, the controller 140 has a CPU, a memory, and an operating program.
- the first rim water spouting commences when the toilet flushing switch (not shown) is operated.
- the controller 140 sends a signal to the switching valve 128, and the switching valve 128 which had been switched over to the rim spouting side is temporarily switched to the tank side.
- the controller 140 sends a signal to the electromagnetic valve 122, releasing it so that flush water is caused to flow into the electromagnetic valve 128.
- the controller 140 sends a signal to the switchover valve 128 switching the switching valve 128, which had been temporarily switch to the tank side over to the rim water spouting side.
- flush water supplied from the water main flows into the constant flow valve 120 via the stopcock 142a, the splitter hardware 142b, and the strainer 142c.
- the flow rate of the flush water is limited to a predetermined flow rate by the constant flow valve 120 as it flows through that valve.
- Flush water that has passed through the constant flow valve 120 passes through the electromagnetic valve 122, the switching valve 128, the rim spout water vacuum breaker 124, and the rim spout water flapper valve 126, and is expelled from the rim water spouting port 118.
- Flush water expelled from the rim water spouting port 118 flows downward as it swirls within the bowl portion 112, and the interior wall of the bowl portion 112 is cleaned.
- jet water spouting is commenced. That is, at time t5 the controller 140 sends a signal to the pressurizing pump 134 causing it to start. Note that the time t5 at which jet water spouting commences is adjusted by the water spout volume adjustment means built in to the controller 140, as discussed below. As shown in Fig. 18 , in the present embodiment the electromagnetic valve 122 is open even during jet water spouting, And because the switching valve 128 remains switched over to the rim water spouting side, water spouting from the rim water spouting port 118 is continued in parallel with jet water spouting.
- the rpm of the pressurizing pump 134 which was turned on a time t5 rises to 1000 rpm by time t6, and this rpm is maintained until time t7.
- the controller causes the rpm of the pressurizing off 134 to rise increasing the rpms up to 3500 rpm by the time t8. This rpm is maintained during his siphon start-up zone from time t8 until time t9. by causing the pressure in pump 134 rpm to rise, flush water in the holding tank 132 is expelled from the jet water spouting port 116 at a large flow rate. This causes the drain trap pipe 114 to fill up rapidly, such that the site in effect quickly starts.
- the controller 140 reduces the pressurizing pump 134 rpms, which drop down to 2600 rpm. This rpm is maintained from time t9 for a predetermined period of time, which is the siphon continuation zone.
- the flow rate expelled from the jet water spouting port 116 is also reduced.
- the flow rate expelled from the jet water spouting port 116 in the siphon continuation zone is a sufficient flow rate to maintain the siphon action which arose in the siphon start-up zone, therefore the siphon action is continued virtually until the siphon continuation zone ends.
- the siphon action can be continued for a long time while keeping the volume of flush water expelled from the jet water spouting port 116 to a low level.
- the controller 140 next again causes the pressurizing pump 134 rpm to rise; vacuum is raised to 3500 rpm by time t10. this rpm is maintained during the blow zone from time t10 to time t11.
- blow zone ending time t11 is adjusted by the spout water volume adjustment means 140b built into the controller 140, as discussed below.
- the water level in the holding tank 132 drops due to jet water spouting, but in normal use it does not drop to the water level at which the lower end float switch 132c turns ON. If the water level in the holding tank 132 drops abnormally due to some problem such that the lower end float switch 132c turns ON, the controller 140 performs an emergency shut off of the pressurizing pump 134 to prevent damage to the pressurizing pump 134.
- the controller 140 reduces the pressurizing pump 134 rpm, and the pressure pump 134 stops by time t12. Rim water spouting continues after the jet water spouting has ended, so the accumulated water level in the bowl portion 112 rises.
- the controller 140 sends a signal to the switching valve 128, and the switching valve 128, which had been switched to the rim water spouting side, is now switched to the tank water supply side.
- the switching valve 128 is completely switched over to the tank water supply side by time t14, after which all supplied flush water flows into the holding tank 132.
- the post rim flush time which is the time from t 11 when the jet water spouting ends to the time t13 when a signal is sent to the switching valve 128, is adjusted by the water spouting volume adjustment means 140b built into the controller as discussed below.
- the clock means 148a built into the controller 140 begins measuring the water replenishment time.
- the inflow of flush water to the holding tank 132 causes the water level in the holding tank 132 to rise, and at time t15 the water level rises to the predetermined water level and the upper end float switch 132 turns ON.
- the controller 140 sends a signal to the electromagnetic valve 122 causing it to close.
- the clock means 140a measures the water replenishment time after supply water to the tank begins, up until the water level in the holding tank 132 reaches the predetermined water level and the flush water in the holding tank 132 is at the predetermined measured water volume.
- the water spouting volume adjustment means 140b built into the controller 140 adjusts the jet water spouting volume expelled from the jet water spouting port 116 and the rim spouting time over which water is expelled from the rim water spouting port 118 by varying the blow zone time and the post rim flush time based on the water replenishment time measured by the clock means 140a, as discussed below.
- the controller 140 sends a signal to the switching valve 128, switching the switching valve 128 from the tank water supply side to which it had been switched over to the rim water spouting side, thus returning it to the standby state at time t16.
- Fig. 19 is a flow chart showing the spout water volume adjustment means. Note that adjustment of the spout water volume in the present embodiment is executed primarily for the purpose of preventing an insufficiency of flush water or wasted use of flush water due to variations in flow rate between individual constant flow valves 120.
- Step S1 when the toilet flushing switch (not shown) is operated towards the small flush side, the controller 140 outputs a small flush signal to the electromagnetic valve 122 or the like (Step S1).
- adjustment of the spout water volume by the water spouting volume adjustment means 140b is particularly effective in the small flush case when the total volume of flush water expelled is low, and in the present embodiment adjustment of the water spouting volume is performed only for small flushes.
- the issuing of a small flush signal from the controller 140 results in the execution of a toilet flush as described above in Step S2. Note that the volume of flush water spouted at this time is determined by the water spouting volume adjustment means 140b based on the previous flush.
- the default value for the volume of water spouted during flushing is set to be the optimal value for the case in which the constant flow valve 120 passes exactly the designed value of flow rate under normal water pressure. This default value is not changed when water is run through the valve, such as during factory testing or the like. Moreover, when the flush toilet 100 is installed on site and the first small flush is performed in trial use, flushing is executed according to the default value, and the subsequent water replenishment time is referred to for water spouting volume adjustments.
- Step S3 the switching valve 128 is switched over to the holding tank 132 side (time t13 in Fig. 18 ).
- the timer built into the controller 140 begins summing time in Step S4. That is, the clock means 140a begins measuring the water replenishment time.
- switching valve 128 is in a transitional state of being switched, so the flush water flows into both the holding tank 132 and the bowl portion 112.
- the switching about 128 operation is reproducible, individual differences between constant flow valves 120 can be evaluated by measuring the water replenishment time after time t13.
- Step S5 a determination is made as to whether the upper end float switch 132 is ON or not, and processing continues until it turns ON. Note that if the time measured by the clock means 140 exceeds a predetermined time there is a possibility the water will be turned off or stopcock 142a will be closed, therefore this step is forcibly terminated. In this case time measured by the clock means 140a is not used for adjustment of the water spouting volume.
- Step S6 When the water level in the holding tank 132 rises and the upper end float switch 132 turns ON, the system advances to Step S6, where the electromagnetic valve 122 is closed (time t15 in Fig. 18 ).
- Step S7 the count by the timer which had begun to accumulate in Step S4 is stopped, and the water accumulation time for the current flush is ascertained. If the constant flow valve 120 is passing a flow rate which is essentially its nominal value, this water replenishment time will be essentially the designed value time. The water replenishment time will be shorter if the flow rate passed by the constant flow valve 120 is more than the nominal value, and will be longer if the flow rate is less than the nominal value, or if the flush toilet 100 is installed in a low water pressure locality.
- Step S8 a calculation is made of the moving average of the water replenishment time measured on this occasion and in the past.
- the water replenishment times for the most recent 50 iterations, including the most recently measured water replenishment time are averaged. Note that if there have not been 50 measured water replenishment times, all of the past water replenishment times are averaged.
- Step S9 the water spouting volume for the next small flush is determined based on the moving average value of water replenishment times. That is, in the present embodiment, moving average values are divided into three categories, and one of three flushing modes appropriate to each of those is selected.
- the calculated moving average value is essentially the design value, which is to say when the constant flow valve 120 has a nominal flow rate of approximately 11-13 liters/minute
- the pre rim flush time (interval t4-t5 in Fig. 18 ) is set to approximately 4.5 seconds
- the jet water spouting blow zone (interval t10-t11 in Fig. 18 ) is set to approximately 0.94 seconds
- the post rim flush time (interval t11-t13 in Fig.
- the pre rim flush time, the blow zone, and the post rim flush time are set at approximately 4.8 seconds, approximately 0.99 seconds, and approximately 3.9 seconds, respectively.
- the pre rim flush time, the blow zone, and the post rim flush time are set at approximately 4.2 seconds, approximately 0.90 seconds, and approximately 2.6 seconds, respectively. This results in a flush water spouting volume of approximately 1.05 liters, approximately 1.0 liters, and approximately 0.65 liters in each respective period, so that in the overall toilet flush approximately 4.8 liters of flush water are used.
- Step S9 When the next flushing mode is selected in Step S9, a single processing iteration shown in Fig. 19 is completed, and the system returns to the Step S0 standby state.
- the flush toilet of the second embodiment of the present invention varies the rim spouting volume and the jet spouting volume, enabling the supply of an appropriate volume of flush water at all times even when there are large individual variations between constant flow valves, while maintaining the flushing capability of the toilet
- use of the switching value enables the supply of water to the holding tank to be commenced in parallel with post rim flushing, so that the water supply time to the tank after the post rim flushing has completed can be reduced. Moreover, the time until the drain trap pipe is sealed, and the tank supply completion time, can be appropriately set by an appropriate allocation of flush water by the switching valve.
- the water replenishment time was measured by measuring the predetermined held water volume at which the holding tank is full as the measured held water volume, but the measured held water volume can also be set to be lower than the predetermined held water volume.
- a third sensor for detecting the measured held water volume is provided between the upper end float switch and the lower end float switch, and the volume of spout water is adjusted using the time after water supply to the tank is commenced until the third sensor detects the measured held water volume as the water replenishment time.
- the held water volume was measured using a float switch, but the held water volume can also be measured using any optional sensor, such as a pressure sensor disposed within the holding tank, or the like.
- rim spout water volume and the jet spout water volume were adjusted in accordance with the water replenishment time, but a flush toilet could also be constituted to adjust only one of those.
- a flush toilet could also be constituted so that only the pre rim flush time and the post rim flush time are adjusted.
- the pre rim flush time would be set to approximately 4.5 seconds, the blow zone to approximately 0.94 seconds, and the post rim flush time to approximately 3.2 seconds, with the flush water volume in each time period being approximately 0.9 liters, approximate 1.0 liters, at approximately 0.65 liters respectively, and the overall toilet flush being approximately 4.5 liters.
- the respective flush times would be approximately 5.4 seconds, approximately 0.94 seconds, and approximately 3.9 seconds, and the flush water volume in each period would be approximately 0.9 liters, approximately 1.0 liters, and approximately 0.65 liters, for an overall toilet flush of approximately 4.4 liters. If a constant flow valve has a flow rate of less than approximately 13 liters/minute, the respective flush times would be approximately 4.2 seconds, approximately 0.94 seconds, and approximately 2.6 seconds, and the flush water volume in each period would be approximately 1.05 liters, approximately 1.0 liters, and approximately 0.65 liters, for an overall toilet flush of approximately 4.8 liters.
- toilet paper, floating waste, and the like can be collected in the center of accumulated water by the water spouting coming from the pre rim flush.
- This enables the effective discharge of floating waste and the like into the drain trap when a siphon action is generated.
- the accumulated water level in the bowl portion rises due to the spouting of water in the pre rim flush, such that water head pressure increases and the flush water is forced into the drain trap pipe, facilitating an early start of the siphon effect.
- Jet water spouting is done primarily to start a siphon action, causing the flush water and waste in the bowl portion to be discharged, but during jet water spouting in the blow zone (times t10-t11 in Fig. 18 ) there is an effect whereby floating waste and the like trying to return to the bowl portion from midway along the drain trap pipe pass over the highest portion of the drain trap pipe and are dropped into the down pipe.
- the pressurizing pump rpm in the siphon start-up region was 3500 rpm, 2600 rpm in the siphon continuation region (time t9-t10 in Fig. 18 ), and 3500 rpm in the blow zone, but these rpms and the duration of each of region can be changed as appropriate.
- the siphon start-up time can be brought further forward by increasing the siphon effect start-up region pressurizing pump rpm to approximately 3600 rpm.
- floating waste and the like attempting to return into the bowl portion can be strongly pushed out by increasing the blow zone pressurizing pump rpm to approximately 3600 rpm, so that even if the blow zone time is shortened, one can expect a similar waste push-out effect.
- lengthening the time period without changing the blow zone rpm permits a more reliable pushing out of floating waste and the like, obtaining the most favorable results in the experiments of the inventors.
- the post rim flush time can be shortened to prevent water waste, and a portion of the flush water thus saved can be directed at the pre rim flush to enable reliable discharge of floating waste.
- jet water spouting it is also effective, in addition to these changes, or independently thereof, to lengthen the blow zone duration.
- the spout water adjustment means adjusted the water spout volume using a moving average of the last 50 water replenishment times, but as a variant, water spouting volume could also be adjusted using another algorithm. For example, the water spouting volume for the next iteration could be determined based on a single most recent water replenishment time. This would enable the adjustment of water spouting volume in response to short-term fluctuations in the water main supply pressure.
- the spout water volume could be adjusted based on the most recent water replenishment time and the water replenishment time previous to that. For example, if the water replenishment time were divided into approximately 5 rank stages, and the gap between the most recent water replenishment time and the water replenishment time prior to that were within approximately 2 stages, a water spouting volume based on the most recent water replenishment time could be used for the next flush. This would enable a balance to be struck between water spouting volume responsiveness and safety.
- the controller could be configured so that when the water replenishment time detected in the most recent toilet flush is longer by a predetermined length of time than the previous water replenishment time, additional water spouting would be added to raise the water level in the bowl portion after the holding tank had been restored to a predetermined held water volume. That is, if the water replenishment time in the most recent toilet flush greatly exceeds the previous water replenishment time, this would mean that the post rim flush, in which flow rate was greatly reduced compared to the previous iteration, would be carried out for just the rim spouting time determined based on the previous toilet flush, when flow rate was high.
- the controller would therefore perform additional water spouting to raise the bowl portion water level so that this type of flush water insufficiency would not occur.
- seal failure can be prevented even when there is a sudden drop in water main pressure, such as when there is simultaneous water main use for toilet flushing and bathing or the like.
- the volume of flush water supplied to the bowl portion is calculated from the rim spout water flow rate corresponding to the most recent water replenishment time, and the post rim flush time determined based on the previous toilet flush (the most recent rim spouting time).
- the insufficiency of flush water is obtained from the calculated flush water volume and the volume of flush water previously recorded as necessary to seal the drain trap type, and this insufficient portion of flush water is supplied to the bowl portion as additional spout water.
- the trap drain can be reliably sealed, and water wastage caused by excessive additional spout water volume can be prevented.
- an additional spout water volume could also be preset in accordance with the number of ranks in the interval between the most recent water replenishment time and the previous water replenishment time, such that a sufficient volume is preset irrespective of the insufficiency of flush water.
- additional water spouting could also be implemented through the rim spout water port by appropriately releasing spout water via an electromagnetic valve, or an electromagnetic valve and a switching valve, or by switching, or through the jet water spouting port by operating a pressurizing pump at low-speed.
- additional water spouting could also be implemented through an overflow path (not shown) extending from within the holding tank.
- the overflow path could discharge flush water in the holding tank into the bowl portion, preventing an overflow of flush water from the holding tank.
- This overflow path could be configured to connect to the bowl portion via the rim water spouting port or the jet water spouting port.
- the overflow path could be configured to connect to the bowl portion via an opening provided separately from the rim water spouting port and the jet water spouting port.
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- Engineering & Computer Science (AREA)
- Health & Medical Sciences (AREA)
- Life Sciences & Earth Sciences (AREA)
- Hydrology & Water Resources (AREA)
- Public Health (AREA)
- Water Supply & Treatment (AREA)
- Aviation & Aerospace Engineering (AREA)
- Sanitary Device For Flush Toilet (AREA)
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2006236088 | 2006-08-31 | ||
PCT/JP2007/066754 WO2008026633A1 (en) | 2006-08-31 | 2007-08-29 | Flush toilet |
Publications (3)
Publication Number | Publication Date |
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EP2058443A1 EP2058443A1 (en) | 2009-05-13 |
EP2058443A4 EP2058443A4 (en) | 2014-10-15 |
EP2058443B1 true EP2058443B1 (en) | 2017-05-17 |
Family
ID=39135915
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP07806231.2A Active EP2058443B1 (en) | 2006-08-31 | 2007-08-29 | Flush toilet |
Country Status (8)
Country | Link |
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US (1) | US8418277B2 (ko) |
EP (1) | EP2058443B1 (ko) |
JP (1) | JP4941900B2 (ko) |
KR (1) | KR101356186B1 (ko) |
CN (1) | CN101517171B (ko) |
CA (1) | CA2661847C (ko) |
TW (1) | TW200811340A (ko) |
WO (1) | WO2008026633A1 (ko) |
Cited By (1)
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EP4428313A1 (en) * | 2023-03-10 | 2024-09-11 | Roca Sanitario, S. A. | A toilet flush tank, a toilet flushing device comprising the toilet flush tank, and a toilet comprising the toilet flushing device |
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2007
- 2007-08-29 JP JP2008532087A patent/JP4941900B2/ja active Active
- 2007-08-29 WO PCT/JP2007/066754 patent/WO2008026633A1/ja active Application Filing
- 2007-08-29 TW TW096132083A patent/TW200811340A/zh unknown
- 2007-08-29 CA CA2661847A patent/CA2661847C/en active Active
- 2007-08-29 US US12/438,965 patent/US8418277B2/en active Active
- 2007-08-29 EP EP07806231.2A patent/EP2058443B1/en active Active
- 2007-08-29 CN CN2007800338726A patent/CN101517171B/zh active Active
- 2007-08-29 KR KR1020097004184A patent/KR101356186B1/ko active IP Right Grant
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
EP4428313A1 (en) * | 2023-03-10 | 2024-09-11 | Roca Sanitario, S. A. | A toilet flush tank, a toilet flushing device comprising the toilet flush tank, and a toilet comprising the toilet flushing device |
WO2024188970A1 (en) * | 2023-03-10 | 2024-09-19 | Roca Sanitario, S. A. | A toilet flush tank, a toilet flushing device comprising the toilet flush tank, and a toilet comprising the toilet flushing device |
Also Published As
Publication number | Publication date |
---|---|
JP4941900B2 (ja) | 2012-05-30 |
CN101517171A (zh) | 2009-08-26 |
EP2058443A4 (en) | 2014-10-15 |
EP2058443A1 (en) | 2009-05-13 |
TWI339700B (ko) | 2011-04-01 |
CN101517171B (zh) | 2011-01-19 |
KR20090061625A (ko) | 2009-06-16 |
CA2661847A1 (en) | 2008-03-06 |
JPWO2008026633A1 (ja) | 2010-01-21 |
CA2661847C (en) | 2015-04-14 |
US8418277B2 (en) | 2013-04-16 |
WO2008026633A1 (en) | 2008-03-06 |
TW200811340A (en) | 2008-03-01 |
KR101356186B1 (ko) | 2014-01-24 |
US20100077544A1 (en) | 2010-04-01 |
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